Soy Biodiesel and Petrodiesel Emissions Differ in Size, Chemical

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Soy Biodiesel and Petrodiesel Emissions Differ in Size, Chemical Composition and Stimulation of Inflammatory Responses in Cells and Animals Naomi K. Fukagawa,*,† Muyao Li,† Matthew E. Poynter,† Brian C. Palmer,† Erin Parker,† John Kasumba,‡ and Britt A. Holmén‡ †

Department of Medicine and ‡School of Engineering, University of Vermont, Burlington, Vermont 05405, United States S Supporting Information *

ABSTRACT: Debate about the biological effects of biodiesel exhaust emissions exists due to variation in methods of exhaust generation and biological models used to assess responses. Because studies in cells do not necessarily reflect the integrated response of a whole animal, experiments were conducted in two human cell lines representing bronchial epithelial cells and macrophages and female mice using identical particle suspensions of raw exhaust generated by a Volkswagen light-duty diesel engine using petrodiesel (B0) and a biodiesel blend (B20: 20% soy biodiesel/80% B0 by volume). Tailpipe particle emissions measurement showed B0 generated two times more particle mass, larger ultrafine particle number distribution modes, and particles of more nonpolar organic composition than the B20 fuel. Biological assays (inflammatory mediators, oxidative stress biomarkers) demonstrated that particulate matter (PM) generated by combustion of the two fuels induced different responses in in vitro and in vivo models. Concentrations of inflammatory mediators (Interleukin-6, IL-6; Interferon-gamma-induced Protein 10, IP-10; Granulocytestimulating factor, G-CSF) in the medium of B20-treated cells and in bronchoalveolar lavage fluid of mice exposed to B20 were ∼20−30% higher than control or B0 PM, suggesting that addition of biodiesel to diesel fuels will reduce PM emissions but not necessarily adverse health outcomes.



INTRODUCTION Biodiesel, a renewable fuel derived from a variety of animal or vegetable fats, is a drop-in alternative to petroleum diesel. Since 2005, U.S. energy policy has mandated increases in the quantity of renewable fuels used for transportation, including “biomassbased diesel”.1−3 Hence, the expected increase in future use of biodiesel emphasizes the critical need to understand the health and environmental effects of biodiesel combustion. Data about the biological and health effects of biodiesel emissions are very limited and have stimulated debate about the pros and cons of changing fuel supplies.4−7 Comparing the results of different health effects studies for exhaust particles produced by biodiesel and petrodiesel combustion is difficult because of differences in the experimental methods used, including age and type of diesel engine, drive cycle, fuel feedstock, and percentage in the blended fuel. Early publications lack information on fuel composition and emissions sampling procedures. Diesel engine emissions are an important source of particulate matter (PM) in ambient air and many occupational settings. New diesel engines have been engineered to yield lower regulated emissions (PM, CO, HC, NOx), but exposure continues to pose adverse health risks due to increased ultrafine (particle diameter, Dp ≤ 100 nm) and nanoparticle (Dp ≤ 50 nm) emissions.5−7 The commercial biodiesel blend most © 2013 American Chemical Society

commonly used in on-road vehicles in the U.S. is a 20% soybean biodiesel blend (B20; 20% biodiesel and 80% petrodiesel, by volume). Only recently has the detailed chemical composition of biodiesel exhaust PM been reported.8,9 Combustion of biodiesel compared to petrodiesel produced lower emissions of CO, hydrocarbons, and PM mass,3,10 smaller diameter ultrafine particles, lower polycyclic aromatic hydrocarbons (PAH) and either lower or higher concentrations of gas-phase carbonyls, depending on the operating conditions of the engine and the composition of the biodiesel fuel.11−13 The mechanisms whereby particles affect health are believed to involve oxidative stress at the cellular level, either induced indirectly by the particles contributing to reactive oxygen species (ROS) production, or directly via ROS-bearing functionalities within the particles. A number of studies have quantified the “oxidative potential” of exhaust particles using an abiotic dithiothreitol (DTT) assay.14,15 While these abiotic tests are informative in a relative sense, they cannot account for the particle/cell interactions Received: Revised: Accepted: Published: 12496

July 16, 2013 September 17, 2013 September 20, 2013 September 20, 2013 dx.doi.org/10.1021/es403146c | Environ. Sci. Technol. 2013, 47, 12496−12504

Environmental Science & Technology

Article

punches of the filters using hexane/dichloromethane followed by methanol in triplicate, concentration under N2 gas, and addition of sample and deuterated phenanthrene internal standard into a TD borosilicate glass vial. The methanol extract was derivatized with pentafluorobenzyl hydroxylamine to quantify polar organic compounds. Polar and nonpolar compound identification was based on the NIST08 mass spectral library match for functional group comparisons of the filter extracts (SI). Individual compounds containing oxygenbearing functional groups were quantified as “polar” (alcohols, aldehydes, acids, esters, ketones) assuming a response factor of 1 for all compounds. This enabled relative comparison of particle organic composition between the fuel types. Sixteen EPA priority PAHs were quantified using extracted ion calibration curves developed using authentic standards. Preparation of Particle Stock Suspensions. Raw exhaust particles collected in ethanol impingers were concentrated via gentle N2 blowdown to generate stock suspensions of approximately 1 mg/mL. PM concentrations of impinger suspensions were determined in triplicate using gravimetric analysis (Cahn C-31 μg balance, 0.001 mg sensitivity) of 100 μL aliquots prepared prior to, during, and after dilution of the stock suspension with Milli-Q water to obtain aqueous solutions with final ethanol concentrations less than 10% v/v to avoid cell death.17 Abiotic Assays. Because PM may inherently induce oxidative stress, ROS production by the PM used in these experiments was examined with the DTT assay.14−16 Because PM may bind small proteins, such as cytokines, and affect concentration measurements, cytokine adsorption to PM was determined by treating particles with different cytokine concentrations and measuring levels of unbound cytokine in the medium. In Vitro and In Vivo Particle Exposures. In vitro cell experiments were conducted with human THP-1 monocytes differentiated into macrophages with phorbol myristic acid (PMA) and BEAS-2B cells (ATCC, Manassas, VA). Cells seeded at 3 × 106 per 60 cm2 were directly treated with the B0 or B20 engine exhaust particles at final concentrations of 10 and 20 μg/mL and the same volume of 8% ethanol as the vehicle control (final ethanol concentration